Electronic device stand and electronic device accessory

By changing the main body of the bracket to a magnetically insulated body and using a stable connection between the connecting transition piece and the connector, the problems of reduced wireless charging efficiency and unstable connection are solved, achieving a stable connection and efficient charging.

CN224459851UActive Publication Date: 2026-07-03SHENZHEN LANHE TECHNOLOGIES CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
SHENZHEN LANHE TECHNOLOGIES CO LTD
Filing Date
2025-06-09
Publication Date
2026-07-03

AI Technical Summary

Technical Problem

Existing bracket protective cases suffer from reduced charging efficiency due to the magnetic field caused by magnetic force during wireless charging. Furthermore, the non-metallic magnetically insulated body is difficult to securely connect with the metal connectors, affecting its service life.

Method used

A magnetically insulated body is used as the main body of the support component, and a connecting transition piece is embedded in the magnetically insulated body. The exposed part is welded or riveted to the connecting piece to form a stable connection, avoid the magnetic force affecting the magnetic field, and enhance the connection stability.

Benefits of technology

It effectively reduces the impact of the bracket on wireless charging, improves connection stability, extends service life, and reduces the probability of foreign object detection.

✦ Generated by Eureka AI based on patent content.

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Abstract

This application discloses an electronic device bracket and an electronic device accessory. The electronic device bracket includes a bracket component, a connecting transition component, and a connector. The connector is connected to the bracket component via the connecting transition component. The bracket component includes a magnetically insulating body and a magnetic component disposed on the magnetically insulating body. The connecting transition component includes an embedded portion and an exposed portion. The embedded portion is embedded within the magnetically insulating body, and the exposed portion is exposed outside the magnetically insulating body and connected to the connector. In the electronic device bracket disclosed in this application, the main body of the bracket component is replaced with a magnetically insulating body, so that when the magnetically insulating body is subjected to magnetic force, it will not affect the original magnetic field, effectively reducing the impact of the bracket component on wireless charging transmission. Moreover, embedding the connecting transition component into the magnetically insulating body and forming a connection with it facilitates a stable connection between the connecting transition component and the magnetically insulating body, while the exposed portion can also form a stable connection with the connector.
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Description

Technical Field

[0001] This application relates to the field of electronic device accessories technology, and in particular to an electronic device bracket and electronic device accessories. Background Technology

[0002] Users typically protect their electronic devices by using protective cases on their phones and other electronic devices. With the continuous development of long and short video technologies, users often choose protective cases with built-in stands to free their hands while watching videos. These types of cases not only protect the electronic devices but also support the phone for video viewing.

[0003] As wireless charging technology has developed and matured, it has become increasingly convenient for mobile phones. Since Apple released MagSafe technology, users can use the magnets inside their phones to magnetically attach the wireless charger to the back of the phone for charging, without interfering with phone use. However, with protective cases, the distance between the phone's magnets and the wireless charger increases, weakening the magnetic attraction and making the charger more prone to falling off. This necessitates the use of magnets on the protective case itself to hold the wireless charger. This results in a proliferation of functional components (magnets, stands, etc.) on protective cases, while the limited space within the case itself prevents the inclusion of too many.

[0004] Based on this, a new type of phone case has emerged on the market. By placing magnets on the stand, it not only provides support but can also be stored on the back of the case. The wireless charger can also be magnetically attached to the stand for wireless charging. This combination significantly saves space in the phone case, but it also introduces another technical problem. Current wireless charging primarily uses electromagnetic induction technology, which generates a changing magnetic field through a coil in the charger, inducing an electromotive force in the receiver of the phone and generating a current to charge it. However, existing phone cases, designed to ensure support strength and lifespan, are susceptible to magnetic forces, affecting the magnetic field of the wireless charger and leading to reduced charging efficiency and charging interruptions. Utility Model Content

[0005] This application discloses an electronic device bracket and an electronic device accessory.

[0006] In a first aspect, this application discloses an electronic device bracket, which is configured to support an electronic device. The electronic device bracket includes a bracket, a connecting transition member, and a connector. The connector is connected to the bracket through the connecting transition member, and the bracket is connected to the electronic device or electronic device accessories through the connector.

[0007] The bracket includes a magnetically insulating body and a magnetic component disposed on the magnetically insulating body, the magnetic component being used to attract the wireless charger;

[0008] The connecting transition member includes an embedded part and an exposed part. The embedded part is embedded in the magnetically insulating body, and the exposed part is exposed outside the magnetically insulating body and connected to the connecting member.

[0009] Compared to existing technologies, the electronic device holder disclosed in this application replaces the main body of the holder with a magnetically insulated body. This ensures that the magnetically insulated body does not affect the original magnetic field when subjected to magnetic force, effectively reducing the impact of the holder on wireless charging transmission. Furthermore, the wireless charger can be magnetically attached to the back of the phone via the magnetic components on the holder.

[0010] Furthermore, considering that connectors are typically made of metal, when the main body of the support component is set as a magnetically insulated body, it is difficult for the metal connector to form a stable connection with the magnetically insulated body through hinges, riveting, or welding when the magnetically insulated body is connected to the connector. This may damage the magnetically insulated body or affect its service life. To address this, this application embeds a connecting transition piece into the magnetically insulated body. When the connecting transition piece is connected to the magnetically insulated body, embedding the embedded part into the magnetically insulated body facilitates a stable connection between the connecting transition piece and the magnetically insulated body. Considering that the connecting transition piece needs to be exposed for connection with the connector, the exposed part is made to protrude from the magnetically insulated body. The exposed part is then connected to the connector through welding, hinges, or riveting. Specifically, the magnetically insulated body encloses the embedded part, forming a stable connection between the magnetically insulated body and the connecting transition piece. The connecting transition piece is then connected through welding, hinges, or riveting. In this way, a stable connection between the magnetically insulated body and the connector is achieved without damaging or affecting the magnetically insulated body.

[0011] As an alternative implementation, the connecting transition member includes a first end and a second end opposite to each other, the embedded portion is located at the first end, the exposed portion is located at the second end, and the exposed portion extends in a direction away from the magnetically insulating body.

[0012] When the connecting transition piece is connected to the magnetically insulating body, the first end is embedded into the magnetically insulating body. This embedding facilitates a stable connection between the two parts. Considering that the connecting transition piece needs to be exposed for connection with the connector, the second end is exposed outside the magnetically insulating body. Furthermore, extending the second end away from the connection side allows the exposed portion to be further away from the magnetically insulating body. This prevents damage to the structure of the magnetically insulating body when the exposed portion is connected to the connector.

[0013] As an optional implementation, the exposed portion is provided with a rolled portion, and the electronic device bracket further includes a rotating shaft, which is inserted into the rolled portion and the connector to allow the magnetically insulated body to be rotatably connected to the connector.

[0014] The connector, via a rolled section and a rotating shaft, forms a rotatable connection with the magnetically insulated body. This allows users to adjust the support angle of the electronic device bracket by rotating the magnetically insulated body, thus providing multi-angle support to meet the user's needs for using the electronic device from different angles.

[0015] As an alternative implementation, the connecting transition member is embedded in the magnetically insulating body, which has a first surface and a second surface opposite to each other along its thickness direction. The opposite sides of the embedded portion are covered by the first surface and the second surface, respectively. The first surface is provided with an opening, which is configured to expose the exposed portion to the magnetically insulating body.

[0016] In other words, only a portion of the connecting transition piece is exposed through the opening in the magnetically insulating body, i.e., the exposed part, while the majority is enclosed by the magnetically insulating body, i.e., the embedded part. By being wrapped by the first surface and the second surface in a layered manner, the connecting transition piece can form a stable connection with the magnetically insulating body, while also being exposed through the opening on the first surface to connect with the connecting piece.

[0017] As an alternative implementation, the opening extends in a direction away from the magnetically insulating body to penetrate the edge of the first surface.

[0018] Since the exposed portion also extends away from the magnetically insulating body, when the opening extends through the edge of the first surface in a direction away from the magnetically insulating body, the exposed portion is exposed at the edge of the first surface. In this way, the connector can be connected to the exposed portion from the edge of the first surface, away from the magnetically insulating body, thus avoiding damage to the magnetically insulating body when the exposed portion is connected to the connector.

[0019] As an alternative implementation, the embedded portion is located on the outer periphery of the exposed portion, the exposed portion having a third surface and a fourth surface opposite each other along its thickness direction, the third surface being covered by the second surface, and the fourth surface being exposed to the magnetically insulating body through the opening.

[0020] When the connecting transition piece is connected to the magnetically insulating body, the entire embedded part is located inside the magnetically insulating body and is enclosed by the magnetically insulating body. At the same time, only the fourth surface of the exposed part is exposed through the opening, and the third surface is covered by the second surface of the magnetically insulating body, so that the exposed part is also enclosed by the magnetically insulating body, thereby improving the connection stability between the connecting transition piece and the magnetically insulating body.

[0021] As an alternative implementation, the connector is welded to the exposed portion, or the connector is riveted to the exposed portion.

[0022] When the connector is connected to the exposed part of the connecting transition piece by welding or riveting, the connector can form a stable connection with the connecting transition piece, preventing the connector from detaching from the connecting transition piece.

[0023] As an alternative implementation, the exposed portion has a U-shaped structure and includes a main body portion and a protruding portion. The embedded portion surrounds the outer periphery of the main body portion, and the protruding portion extends to the edge of the magnetically insulating body in a direction away from the main body portion. The end face of the protruding portion is covered by the magnetically insulating body, or the end face of the protruding portion is exposed to the magnetically insulating body.

[0024] When the exposed portion is designed, it has a convex shape, extending towards the edge of the magnetically insulating body away from the main body. This allows the protruding portion to connect to the connector away from the magnetically insulating body. Because the protruding portion is away from the magnetically insulating body, when the connector moves relative to the protruding portion, the interference of the magnetically insulating body on the connector's movement is reduced. Furthermore, when the protruding portion is welded to the connector, damage to the magnetically insulating body is minimized.

[0025] In addition, if the end face of the protruding part is also covered by the magnetically insulated body, the contact area between the connecting transition piece and the magnetically insulated body is increased, which can improve the connection stability between the magnetically insulated body and the connecting transition piece.

[0026] As an optional implementation, the fourth surface has a protruding connecting portion, and the connector has a connecting hole, which is fitted onto the connecting portion so that the connector is positioned or fixed on the exposed portion.

[0027] When the connector and the connecting transition piece are connected, a connecting part is provided on the fourth surface, and a connecting hole is opened on the connector so that the connecting hole is fitted on the connecting part. This facilitates the positioning and installation of the connector and the connecting transition piece, and also enables the connector and the connecting transition piece to form a stable riveting, thereby improving the connection stability between the connector and the connecting transition piece.

[0028] As an alternative implementation, the surface of the end of the connecting portion away from the fourth surface is lower than or flush with the first surface;

[0029] And / or, the connecting portion includes a plurality of such connecting portions, which are spaced apart.

[0030] On the one hand, when setting the connecting part, along the thickness direction of the support member, the surface of the connecting part can be lower than or flush with the first surface to avoid the surface of the connecting part protruding from the first surface, thus preventing the connecting part from being excessively exposed and affecting the appearance of the support member. Moreover, if the surface of the connecting part protrudes too much when the connecting member is connected to the connecting part, it will block the contact between the connecting member and the fourth surface, causing a gap between the connecting member and the fourth surface, which will affect the stable connection between the connecting member and the connecting transition member. In other words, setting the surface of the connecting part to be lower than or flush with the first surface makes it easier for the connecting member to form a tight connection with the exposed fourth surface, thereby improving the stability of the connecting member and the connecting transition member.

[0031] On the other hand, when multiple connecting parts are provided, multiple connecting holes are provided on the connecting parts for connection, so that the connecting parts and the connecting transition parts form multi-point connections, which is beneficial to improving the stability of the connecting parts and the connecting transition parts.

[0032] As an alternative implementation, the magnetically insulating body is constructed as an annular or circular structure, and the connecting transition member includes a first side and a second side opposite to each other in the circumferential direction of the support member. Both the first side and the second side extend in the circumferential direction of the support member and are both wrapped by the magnetically insulating body.

[0033] In the circumferential direction of the support member, the first side and the second side are located on both sides of the embedded part, and the first side and the second side are covered by the magnetically insulating body. That is to say, the two sides of the embedded part in the circumferential direction of the support member are located within the magnetically insulating body, so that the connecting transition member can be stably covered within the magnetically insulating body, further improving the connection stability between the connecting transition member and the magnetically insulating body, and avoiding the situation where the connecting transition member is only partially covered within the magnetically insulating body, which could lead to the connecting transition member detaching from the magnetically insulating body.

[0034] Along the thickness direction of the support member, the magnetically insulating body has a first surface. Any point on the projection of the edge of the first side onto the first surface forms a first line with the center of the magnetically insulating body. Any point on the projection of the edge of the second side onto the first surface forms a second line with the center of the magnetically insulating body. An angle α is formed between the first line and the second line, and the range of α is 15°-90°.

[0035] When α is between 15° and 90°, the embedded part can occupy 1 / 25 to 1 / 4 of the circumference of the magnetically insulating body. When the magnetically insulating body encloses the embedded part, on the one hand, if α is large, the embedded part occupies a large proportion within the magnetically insulating body, leading to an increased proportion of metal within the magnetically insulating body. This may trigger FOD (Foreign Object Detection) in the wireless charger, affecting the wireless charging effect. On the other hand, if α is small, the embedded part occupies a small proportion within the magnetically insulating body, which is not conducive to a stable connection between the connecting transition piece and the magnetically insulating body, thus affecting the stable connection between the connector and the magnetically insulating body.

[0036] Therefore, controlling α within the range of 15°-90° not only reduces the probability of the metal connecting transition piece triggering FOD in the wireless charger, but also enables the connecting transition piece to form a stable connection with the magnetically insulated body.

[0037] As an optional implementation, the magnetically insulating body is further provided with a handle position. The magnetically insulating body is constructed as an annular or circular structure. Along the radial direction of the support member, the handle position and the connecting transition member are located at opposite ends of the magnetically insulating body.

[0038] Typically, the magnetically insulated body can be attached to the surface of electronic devices such as mobile phones or phone cases using connectors. Based on this, a handle can be provided on the magnetically insulated body, allowing users to easily lift it up and facilitating daily use of the electronic device stand.

[0039] As an optional implementation, the magnetic component includes a first sub-magnetic component and a second sub-magnetic component, wherein the first sub-magnetic component is arranged circumferentially along the magnetically insulating body and is located between one end of the handle position and one end of the connecting transition component;

[0040] The second sub-magnetic component is arranged circumferentially along the magnetically insulating body and is located between the other end of the handle position and the other end of the connecting transition component.

[0041] In other words, when the first and second sub-magnetic components are housed within the magnetically insulating body, the magnetically insulating body encloses both components in its thickness direction, allowing them to form a stable connection. Furthermore, both the first and second sub-magnetic components are positioned between the handle and the connecting transition piece; that is, magnetic components are present within the magnetically insulating body on both sides of the handle and the connecting transition piece. This ensures that the magnetism is evenly distributed across the magnetically insulating body, facilitating a stable magnetic attachment of the wireless charger.

[0042] As an optional implementation, the two ends of the connecting transition member are respectively spaced apart from the first sub-magnetic member and the second sub-magnetic member, and the magnetic insulating body is filled between the connecting transition member and the first sub-magnetic member and the second sub-magnetic member.

[0043] On the one hand, since the first sub-magnetic component has magnetic attraction, and the connecting transition component is made of metal, when the first sub-magnetic component and the connecting transition component are placed inside the magnetically insulating body, their positions are relatively close before the magnetically insulating body melts and encapsulates them. This may cause the first sub-magnetic component to attract the connecting transition component. Therefore, setting the first sub-magnetic component and the connecting transition component alternately is beneficial for the arrangement of the connecting transition component within the magnetically insulating body.

[0044] Similarly, since the second sub-magnetic component has magnetic attraction, and the connecting transition component is made of metal, when the magnetic insulating body contains the second sub-magnetic component and the connecting transition component, their close proximity before the magnetic insulating body completely encapsulates them may cause the second sub-magnetic component to attract the connecting transition component. Therefore, spacing the second sub-magnetic component and the connecting transition component apart is beneficial for the arrangement of the connecting transition component within the magnetic insulating body.

[0045] Furthermore, since the first sub-magnetic component, the second sub-magnetic component, and the connecting transition component can all be made of metal, the first sub-magnetic component and the second sub-magnetic component are spaced apart from the connecting transition component in the circumferential direction of the bracket component. This allows the magnetic insulation body to be free of metal material in its circumferential direction, thereby reducing the proportion of metal material in the magnetic insulation body. This reduces the probability of FOD (Foreign Object Defect) and thus reduces the impact on the wireless charging effect.

[0046] Secondly, this application discloses an electronic device accessory, including:

[0047] Accessories main body; and,

[0048] As described in the first or second aspect, the hinge is configured to connect the connecting transition of the electronic device bracket to the accessory body.

[0049] As an alternative implementation, the accessory body is an electronic device protective case, or the accessory body is a ring-shaped support.

[0050] In the electronic device accessory disclosed in this application, a metal connecting transition piece is embedded within a non-metallic magnetically insulating body, and then a hinge is used to connect the transition piece to the accessory body. Since the hinge and the magnetically insulating body form a stable connection through the connecting transition piece, when the hinge is connected to the accessory body, a stable connection is formed between the magnetically insulating body and the accessory body, preventing the magnetically insulating body from detaching from the accessory body.

[0051] Compared with the prior art, the beneficial effects of this application are as follows:

[0052] Compared to existing technologies, the electronic device holder disclosed in this application replaces the main body of the holder with a magnetically insulated body. This ensures that the magnetically insulated body does not affect the original magnetic field when subjected to magnetic force, effectively reducing the impact of the holder on wireless charging transmission. Furthermore, the wireless charger can be magnetically attached to the back of the phone via the magnetic components on the holder.

[0053] Furthermore, considering that connectors are typically made of metal, when the main body of the support component is set as a magnetically insulated body, it is difficult for the metal connector to form a stable connection with the magnetically insulated body through hinges, riveting, or welding when the magnetically insulated body is connected to the connector. This may damage the magnetically insulated body or affect its service life. To address this, this application embeds a connecting transition piece into the magnetically insulated body. When the connecting transition piece is connected to the magnetically insulated body, embedding the embedded part into the magnetically insulated body facilitates a stable connection between the connecting transition piece and the magnetically insulated body. Considering that the connecting transition piece needs to be exposed for connection with the connector, the exposed part is made to protrude from the magnetically insulated body. The exposed part is then connected to the connector through welding, hinges, or riveting. Specifically, the magnetically insulated body encloses the embedded part, forming a stable connection between the magnetically insulated body and the connecting transition piece. The connecting transition piece is then connected through welding, hinges, or riveting. In this way, a stable connection between the magnetically insulated body and the connector is achieved without damaging or affecting the magnetically insulated body. Attached Figure Description

[0054] To more clearly illustrate the technical solutions in the embodiments of this application, the drawings used in the embodiments will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this application. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.

[0055] Figure 1 This is a schematic diagram of a structure of an electronic device bracket disclosed in an embodiment of this application;

[0056] Figure 2 for Figure 1 An exploded view of an electronic device bracket in a diagram;

[0057] Figure 3 This is a schematic diagram of a support component disclosed in an embodiment of this application;

[0058] Figure 4 This is an exploded view of the bracket component disclosed in the embodiments of this application;

[0059] Figure 5 This is a side view of the electronic device bracket disclosed in an embodiment of this application;

[0060] Figure 6 for Figure 5 Sectional view at point AA;

[0061] Figure 7 This is a schematic diagram of another structure of the bracket disclosed in the embodiments of this application;

[0062] Figure 8 This is a schematic diagram of a connecting transition component disclosed in an embodiment of this application;

[0063] Figure 9 for Figure 4 Side view;

[0064] Figure 10 This is another structural schematic diagram of the electronic device bracket disclosed in the embodiments of this application;

[0065] Figure 11 for Figure 10 Sectional view at point BB;

[0066] Figure 12 for Figure 11 A magnified view of a section at point C;

[0067] Figure 13 This is a schematic diagram of the structure of an electronic device accessory disclosed in an embodiment of this application;

[0068] Figure 14 This is another structural schematic diagram of the electronic device accessory disclosed in the embodiments of this application.

[0069] Explanation of reference numerals in the attached figures:

[0070] 100. Electronic device bracket; 1. Bracket component; 11. Magnetic insulating body; 1a. First surface; 1b. Second surface; 1c. Handle position; 11a. Opening; 12. First part; 13. Second part; 2. Connecting transition piece; 2f. First connecting line; 2g. Second connecting line; 20. Embedded part; 21. Exposed part; 211. Main body part; 212. Protruding part; 213. Rolled part; 21a. Third surface; 21b. Fourth surface; 22. First end; 23. Second end; 24. First side; 25. Second side; 26. Connecting part; 3. Connector; 4. First sub-magnetic component; 5. Second sub-magnetic component;

[0071] 200. Electronic equipment accessories; 201. Accessory body. Detailed Implementation

[0072] The technical solutions of the embodiments of this application will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of this application, and not all embodiments. Based on the embodiments of this application, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of this application.

[0073] In this application, the terms "upper," "lower," "inner," "outer," "middle," and "horizontal," etc., indicate the orientation or positional relationship based on the orientation or positional relationship shown in the accompanying drawings. These terms are primarily for the purpose of better describing this application and its embodiments, and are not intended to limit the indicated device, element, or component to having a specific orientation, or to be constructed and operated in a specific orientation.

[0074] Furthermore, in addition to indicating location or positional relationship, some of the aforementioned terms may also have other meanings. For example, the term "above" may also be used in some cases to indicate a certain dependency or connection relationship. Those skilled in the art can understand the specific meaning of these terms in this application based on the specific circumstances.

[0075] Furthermore, the terms "installation," "setup," "equipped with," "connection," and "linked" should be interpreted broadly. For example, they can refer to a fixed connection, a detachable connection, or an integral structure; they can refer to a mechanical connection or an electrical connection; they can refer to a direct connection or an indirect connection through an intermediate medium, or an internal connection between two devices, components, or parts. Those skilled in the art can understand the specific meaning of these terms in this application based on the specific circumstances.

[0076] Furthermore, the terms "first," "second," etc., are primarily used to distinguish different devices, elements, or components (which may be the same or different in specific type and construction), and are not intended to indicate or imply the relative importance or quantity of the indicated devices, elements, or components. Unless otherwise stated, "a plurality of" means two or more.

[0077] Users typically protect their electronic devices by using protective cases on their phones and other electronic devices. With the continuous development of long and short video technologies, users often choose protective cases with built-in stands to free their hands while watching videos. These types of cases not only protect the electronic devices but also support the phone for video viewing.

[0078] As wireless charging technology has developed and matured, it has become increasingly convenient for mobile phones. Since Apple released MagSafe technology, users can use the magnets inside their phones to magnetically attach the wireless charger to the back of the phone for charging, without interfering with phone use. However, with protective cases, the distance between the phone's magnets and the wireless charger increases, weakening the magnetic attraction and making the charger more prone to falling off. This necessitates the use of magnets on the protective case itself to hold the wireless charger. This results in a proliferation of functional components (magnets, stands, etc.) on protective cases, while the limited space within the case itself prevents the inclusion of too many.

[0079] Based on this, a new type of phone case has emerged on the market. By placing magnets on the stand, it not only provides support but can also be stored on the back of the case. The wireless charger can also be magnetically attached to the stand for wireless charging. This combination significantly saves space in the phone case, but it also introduces another technical problem. Current wireless charging primarily uses electromagnetic induction technology, which generates a changing magnetic field through a coil in the charger, inducing an electromotive force in the receiver of the phone, thus generating current to charge the phone. However, existing phone cases, designed to ensure support strength and lifespan, are susceptible to magnetic forces, affecting the magnetic field of the wireless charger. This can lead to reduced charging efficiency, charging interruptions, and other problems, potentially triggering FOD (Foreign Object Detection) on the wireless charger.

[0080] To address this, the inventors replaced the main body of the support component with a magnetically insulated body. This ensures that the magnetically insulated body does not affect the original magnetic field when subjected to magnetic force, effectively reducing the impact of the support component on wireless charging transmission. Furthermore, the wireless charger can be magnetically attached to the back of the phone using the magnetic components on the support component.

[0081] Further research revealed that when connecting a non-metallic magnetic insulating body to a metallic connector, the non-metallic magnetic insulating body is prone to wear relative to the connector due to frequent movement between them, potentially leading to an unstable connection. Furthermore, the non-metallic magnetic insulating body is difficult to connect to the connector via welding. Consequently, it is challenging to effectively connect the metallic connector to the non-metallic magnetic insulating body through welding or riveting, thus hindering stable installation of the magnetic insulating body and connector.

[0082] In this application, the connecting transition piece is embedded within the magnetically insulating body. When the connecting transition piece and the magnetically insulating body are connected, embedding the part within the magnetically insulating body facilitates a stable connection between the connecting transition piece and the magnetically insulating body. Considering that the connecting transition piece needs to be exposed for connection with the connecting piece, the exposed part is made to protrude from the magnetically insulating body. The exposed part is then connected to the connecting piece by welding, hinge, or riveting. Specifically, the magnetically insulating body encloses the embedded part, ensuring a stable connection between the magnetically insulating body and the connecting transition piece. The connecting transition piece is then connected by welding, hinge, or riveting. Thus, without damaging or affecting the magnetically insulating body, a stable connection can be formed between the magnetically insulating body and the connecting piece.

[0083] The technical solution of this application will be further described below with reference to the embodiments and accompanying drawings.

[0084] Firstly, please refer to the following: Figures 1 to 3 This application discloses an electronic device bracket 100, including a bracket 1, a connecting transition member 2, and a connector 3. The connector 3 is connected to the bracket 1 through the connecting transition member 2, and the bracket 1 is connected to an electronic device or electronic device accessory 200 through the connector 3.

[0085] The support member 1 includes a magnetically insulating body 11 and a magnetic element 4 (5) disposed on the magnetically insulating body 11. The magnetic element is used to attract the wireless charger. The connecting transition member 2 includes an embedded part 20 and an exposed part 21. The embedded part 20 is embedded in the magnetically insulating body 11, and the exposed part 21 is exposed outside the magnetically insulating body 11 and connected to the connector 3.

[0086] Compared to existing technologies, the electronic device holder 100 disclosed in this application replaces the main body of the holder 1 with a magnetically insulated main body 11. This ensures that the magnetically insulated main body 11 does not affect the original magnetic field when subjected to magnetic force, effectively reducing the impact of the holder 1 on wireless charging transmission. Simultaneously, the wireless charger can be magnetically attached to the back of the phone via the magnetic components on the holder 1.

[0087] Furthermore, considering that the connector 3 is usually made of metal and the magnetic insulating body 11 can be made of non-metallic material, when the main body of the bracket 1 is set as the magnetic insulating body 11, it is difficult for the metal connector 3 to form a stable connection with the magnetic insulating body 11 by means of hinge, riveting or welding when the magnetic insulating body 11 is connected to the connector 3, which may damage the magnetic insulating body 11 or affect its service life. In this regard, the present application embeds the connecting transition piece 2 into the magnetic insulating body 11. When the connecting transition piece 2 is connected to the magnetic insulating body 11, embedding the embedded part 20 into the magnetic insulating body 11 is conducive to the connecting transition piece 2 forming a stable connection with the magnetic insulating body 11. Considering that the connecting transition piece 2 needs to be exposed to connect with the connector 3, the exposed part 21 is exposed outside the magnetic insulating body 11, and the exposed part 21 is connected to the connector 3 by means of welding, hinge or riveting. The magnetic insulating body 11 encloses the embedded part 20, so that the magnetic insulating body 11 and the connecting transition member 2 form a stable connection. The connecting transition member 2 is then connected by welding, hinge or riveting. In this way, the magnetic insulating body 11 can form a stable connection with the connecting member 3 without damaging or affecting the magnetic insulating body 11.

[0088] It is understood that the aforementioned metal materials can be iron, steel, alloys (such as stainless steel), etc.

[0089] It is understood that the aforementioned non-metallic materials can be materials such as resin and plastic. For example, the support component 1 can be formed by adding fiber materials such as glass fiber and carbon fiber to non-metallic materials such as resin and plastic, or it can be formed solely by non-metallic materials.

[0090] Optionally, the connector 3 may be a spherical bearing, a hinge, etc., which are not specifically limited in this application.

[0091] In some embodiments, such as Figure 2 As shown, the support component 1 can be a ring structure, that is, the support component 1 can be a closed ring or an open ring. Taking the support component 1 as a closed ring as an example, the support component 1 can be a circular ring, a near-circular ring, or the support component 1 can be a polygonal ring, such as a rectangle, a pentagon, a triangle, etc.

[0092] In some embodiments, the support member 1 may be a circular structure, that is, a circular structure may be formed when the middle part of the ring is closed.

[0093] The following explanation will take the support component 1, which is a circular structure, as an example.

[0094] In order to effectively expose the exposed portion 21 to the magnetically insulating body 11, in some embodiments, the connecting transition member 2 includes a first end 22 and a second end 23 opposite to each other. The first end 22 is embedded in the support member 1, that is, the embedded portion 20 is located at the first end 22, and the second end 23 extends in a direction away from the magnetically insulating body 11 and is exposed to the support member 1, that is, the exposed portion 21 is located at the second end 23.

[0095] For example, when the connecting transition member 2 is connected to the magnetically insulating body 11, embedding the first end 22 into the magnetically insulating body 11 facilitates a stable connection between the connecting transition member 2 and the support member 1. Considering that the connecting transition member 2 needs to be exposed for connection with the connector 3, the second end 23 is exposed outside the magnetically insulating body 11. Furthermore, extending the first end 22 away from the magnetically insulating body 11 allows it to be located away from the connection point between the magnetically insulating body 11 and the connector 3. Since the magnetically insulating body 11 can move relative to the connector 3, the distance of the first end 22 from the connection point prevents interference with the rotational position of the magnetically insulating body 11. Furthermore, extending the second end 23 away from the first end 22 allows the exposed portion 21 to be located away from the magnetically insulating body 11. Thus, when the exposed portion 21 is connected to the connector 3, damage to the structure of the magnetically insulating body 11 is avoided.

[0096] As can be understood from the foregoing, the magnetic insulating body 11 can be made of materials such as resin or plastic. Therefore, when the first end 22 is embedded in the magnetic insulating body 11, the first end 22 can be embedded during the formation of the magnetic insulating body 11. For example, taking the material of the magnetic insulating body 11 as resin, the connecting side 1a of the magnetic insulating body 11 can be melted and covered to encapsulate the first end 22 of the connecting transition member 2. Thus, the first end 22 can be directly wrapped by the magnetic insulating body 11, effectively preventing the first end 22 from detaching from the magnetic insulating body 11 and affecting the connection between the magnetic insulating body 11 and the connecting member 3.

[0097] Furthermore, by exposing the first end 22 outside the magnetic insulating body 11, that is, by exposing the first end 22 of the metal material outside the magnetic insulating body 11, the first end 22 can be connected to the connector 3 by welding, riveting or hinge. Taking welding as an example, when the first end 22 is welded to the connector 3, the sparks generated during welding may splash onto the magnetic insulating body 11. In this application, the first end 22 is set away from the magnetic insulating body 11 to avoid damage to the magnetic insulating body 11 during welding. When the first end 22 extends away from the magnetic insulating body 11, the protruding first end 22 is easy to align with the connector 3 for connection.

[0098] Please see Figure 3In some embodiments, the connecting transition member 2 may be integrally embedded within the magnetically insulating body 11, which has opposing first surfaces 1a and second surfaces 1b in its thickness direction. The opposite sides of the embedded portion 20 are respectively covered by the first surfaces 1a and the second surfaces 1b. The first surface 1a is provided with an opening 11a, which is configured to expose the exposed portion 21 to the magnetically insulating body 11.

[0099] In other words, only a portion of the connecting transition member 2 is exposed through the opening 11a of the magnetically insulating body 11, i.e., the exposed portion 21, while the majority is enclosed by the magnetically insulating body 11, i.e., the embedded portion 20. By being layered and enclosed by the first surface 1a and the second surface 1b, the connecting transition member 2 can form a stable connection with the magnetically insulating body 11, while also being exposed through the opening 11a on the first surface 1a to connect with the connecting member 3.

[0100] In addition, the larger portion of the connecting transition piece 2 located within the magnetic insulation body 11 can enhance the structural strength of the magnetic insulation body 11 and prevent damage to the magnetic insulation body 11 caused by repeated rotation relative to the connecting piece 3 during use.

[0101] It is understood that the first surface 1a can be the side surface of the magnetically insulating body 11 facing away from the back of the electronic device or protective case, and the second surface 1b can be the side surface of the magnetically insulating body 11 facing the back of the electronic device or protective case. The first surface 1a can extend from the first end 22 of the connecting transition member 2 to the second end 23 of the connecting transition member 2. The opening 11a on the first surface 1a can extend to the first end 22 of the connecting transition member 2, thereby at least partially exposing the first end 22 of the connecting transition member 2 relative to the support member 1.

[0102] For example, as can be seen from the foregoing, the magnetic insulating body 11 can be made of materials such as resin or gum. Therefore, after the magnetic insulating body 11 is melted, it can completely cover the connecting transition member 2. Then, an opening 11a is processed on the first surface 1a by grinding, milling or cutting, so that the exposed part 21 of the connecting transition member 2 is exposed to the magnetic insulating body 11.

[0103] Optionally, the opening 11a extends in a direction away from the magnetically insulating body 11 to penetrate the edge of the first surface 1a, that is, to penetrate the side of the magnetically insulating body 11.

[0104] Since the exposed portion 21 also extends in a direction away from the magnetically insulating body 11, when the opening 11a extends in a direction away from the magnetically insulating body 11 and penetrates the edge of the first surface 1a, the opening 11a exposes the exposed portion 21 at the edge of the first surface 1a. In this way, the connector 3 can be connected to the exposed portion 21 from the edge of the first surface 1a, away from the magnetically insulating body 11, thus avoiding damage to the magnetically insulating body 11 when the exposed portion 21 is connected to the connector 3.

[0105] Please see Figure 4 In some embodiments, the exposed portion 21 has a U-shaped structure and includes a main body portion 211 and a protruding portion 212. The embedded portion 20 surrounds the outer periphery of the main body portion 211. The protruding portion 212 extends to the edge of the magnetically insulating body 11 in a direction away from the main body portion 211, and the end face of the protruding portion 212 is covered by the magnetically insulating body 11, or the end face of the protruding portion 212 is exposed to the magnetically insulating body 11.

[0106] For example, when the exposed portion 21 is provided, the exposed portion 21 can have a U-shaped structure, with the protruding portion 212 extending away from the main body portion 211 to the edge of the magnetically insulating body 11, so that the end face of the protruding portion 212 can be exposed through the opening 11a to the edge of the first surface 1a, and the end face of the protruding portion 212 can be connected to the connector 3 away from the magnetically insulating body 11. Since the protruding portion 212 is away from the magnetically insulating body 11, when the protruding portion 212 is connected to the connector 3, the interference of the magnetically insulating body 11 on the movement of the connector 3 can be reduced when the connector 3 moves relative to the protruding portion 212. When the protruding portion 212 is connected to the connector 3, the damage to the magnetically insulating body 11 can be reduced when the protruding portion 212 and the connector 3 are welded.

[0107] Furthermore, if the end face of the protruding portion 212 is also covered by the magnetically insulating body 11, the contact area between the connecting transition piece 2 and the magnetically insulating body 11 is increased, which can improve the connection stability between the magnetically insulating body 11 and the connecting transition piece 2.

[0108] Please see also Figure 3 and Figure 4 As can be seen from the foregoing, the magnetic insulating body 11 is constructed as a ring structure (e.g., a circular ring). In some embodiments, the connecting transition member 2 also has a first side 23 and a second side 25 along the circumferential direction of the magnetic insulating body 11. Both the first side 23 and the second side 25 extend along the circumferential direction of the magnetic insulating body 11 and are both wrapped by the magnetic insulating body 11.

[0109] In the circumferential direction of the magnetically insulating body 11, the first side 23 and the second side 25 are located on both sides of the embedded portion 20, and both the first side 23 and the second side 25 are covered by the magnetically insulating body 11. That is to say, the two sides of the embedded portion 20 in the circumferential direction of the magnetically insulating body 11 are located inside the magnetically insulating body 11, so that the connecting transition member 2 can be stably covered inside the magnetically insulating body 11, further improving the connection stability between the connecting transition member 2 and the magnetically insulating body 11, and avoiding the situation where the connecting transition member 2 is only partially covered inside the magnetically insulating body 11 and may detach from the magnetically insulating body 11.

[0110] In order to ensure that the connecting transition piece 2 can be more securely encased by the magnetically insulating body 11, in some embodiments, the embedded part 20 is located outside or around the exposed part 21, the exposed part 21 having a third surface 21a and a fourth surface 21b opposite to each other along its thickness direction, the third surface 21a being covered by the second surface 1b, and the fourth surface 21b being exposed to the magnetically insulating body 11 through the opening 11a.

[0111] When the connecting transition member 2 is connected to the magnetically insulating body 11, the embedded part 20 is entirely located inside the magnetically insulating body 11 and is enclosed by the magnetically insulating body 11. At the same time, only the fourth surface 21b of the exposed part 21 is exposed through the opening 11a, and the third surface 21a is enclosed by the second surface 1b of the magnetically insulating body 11, so that part of the exposed part 21 is also enclosed by the magnetically insulating body 11, thereby improving the connection stability between the connecting transition member 2 and the magnetically insulating body 11.

[0112] Understandably, in Figure 4 In the example, X indicates the radial direction of the support member 1, Y indicates the circumferential direction of the support member 1, and Z indicates the thickness direction of the support member 1.

[0113] To ensure a stable connection between the connector 3 and the magnetically insulated body 11, this application embeds a connecting transition piece 2 within the magnetically insulated body 11. However, considering that the embedded connecting transition piece 2 is a metal component, there is a possibility that it may trigger FOD (Foreign Object Defect) in the wireless charger. Based on this, this application also designs the structure of the connecting transition piece 2 embedded within the magnetically insulated body 11, as detailed below.

[0114] Please see also Figure 5 and Figure 6 In some embodiments, when the magnetic insulating body 11 is constructed as a ring-shaped structure, the connecting transition member 2 includes a first side 23 in the circumferential direction of the magnetic insulating body 11 and a second side 25 opposite to the first side 23. The first side 23 and the second side 25 both extend in the circumferential direction of the magnetic insulating body 11 and are both located inside the magnetic insulating body 11, so that the magnetic insulating body 11 encloses the first side 23 and the second side 25.

[0115] When the first side 23 and the second side 25 are both wrapped inside the magnetic insulating body 11 and extend along the circumferential direction of the magnetic insulating body 11, the more the first side 23 and the second side 25 are wrapped by the magnetic insulating body 11, the stronger the bonding force between the first side 23 and the second side 25 and the magnetic insulating body 11, that is, the more firmly the connecting transition piece 2 is connected to the magnetic insulating body 11.

[0116] Optionally, from the first surface 1a of the magnetically insulating body 11, any point of the projection of the first side 23 on the first surface 1a is connected to the center of the support member 1 to form a first connecting line 2f, and any point of the projection of the second side 25 on the first surface 1a is connected to the center of the support member 1 to form a second connecting line 2g. An angle α is formed between the first connecting line 2f and the second connecting line 2g, and α can be 15°-90°.

[0117] For example, α can be 15°-20°, 20°-25°, 25°-30°, 30°-35°, 35°-40°, 40°-45°, 45°-50°, 50°-55°, 55°-60°, 60°-65°, 65°-70°, 70°-75°, 75°-80°, 80°-85°, 85°-90°, etc. For example, α can be 15°, 17°, 20°, 23°, 25°, 27°, 30°, 33°, 35°, 37°, 40°, 43°, 45°, 47°, 50°, 53°, 55°, 57°, 60°, 63°, 65°, 67°, 70°, 73°, 75°, 77°, 80°, 83°, 85°, 87°, or 90°, etc.

[0118] When α is between 15° and 90°, the connecting transition piece 2 occupies 1 / 25 to 1 / 4 of the circumference of the support piece 1 in the circumferential direction. When the magnetically insulating body 11 encloses the connecting transition piece 2, on the one hand, if α is large, the proportion of the connecting transition piece 2 within the magnetically insulating body 11 is large, leading to an increase in the proportion of metal within the magnetically insulating body 11, which may cause FOD triggering and affect the wireless charging effect. On the other hand, if α is small, the magnetically insulating body 11 may enclose a smaller portion of the connecting transition piece 2, which is not conducive to a stable connection between the connecting transition piece 2 and the magnetically insulating body 11, thereby affecting the stable connection between the connecting piece 3 and the magnetically insulating body 11.

[0119] Therefore, controlling α within the range of 15°-90° not only reduces the probability of the metal connecting transition piece 2 triggering FOD in the wireless charger, but also enables the connecting transition piece 2 to form a stable connection with the magnetically insulated body 11.

[0120] In one example, when the projections of the first side 23 and the second side 25 onto the first surface 1a are a straight line, any point of the projection of the first side 23 and the second side 25 onto the first surface 1a can be any point on the straight line.

[0121] In another example, when the projections of the first side 23 and the second side 25 onto the first surface 1a are not straight lines, the angle formed by the line connecting the outermost point on the corresponding line to the center of the circle is the maximum value of the angle that can be formed by any two points, and this maximum value is also within the range mentioned above.

[0122] Please see Figure 7 In some embodiments, the exposed portion 21 is provided with a rolled portion 213, and the electronic device bracket 100 also includes a rotating shaft (not shown), which is inserted into the rolled portion 213 and connected to the connector 3 so that the magnetically insulated body 11 is rotatably connected to the connector 3.

[0123] For example, when the exposed part 21 is provided with a rolled part 213, a rotating shaft can be provided on the connector 3. The rolled part 213 is hinged to the rotating shaft, so that the connector 3 and the connecting transition member 2 form a stable connection while the connecting transition member 2 can rotate relative to the connector 3.

[0124] It is understood that the rolled portion 213 can be a single cylindrical structure, that is, the overall shape of the rolled portion 213 is cylindrical, or the rolled portion 213 can be a double cylindrical structure or a multi-cylinder structure, that is, the rolled portion 213 can form two or more cylindrical structures that are hinged to the rotating shaft to realize the rotation of the magnetically insulating body 11 relative to the connecting member 3. This application does not make specific limitations here.

[0125] It is understood that the rolled portion 213 may be a cylindrical structure, a polygonal cylindrical structure, etc., and this application does not make specific limitations here.

[0126] For example, when the exposed portion 21 is provided with a rolled portion 213, taking the connector 3 as a hinge as an example, the exposed portion 21 can be directly connected to the pivot of the connector 3 through the rolled portion 213, without having to be connected to the connecting transition member 2 through the sheet of the connector 3. This helps to avoid the connection between the sheet of the connector 3 and the connecting transition member 2 causing the magnetic insulation body 11 to be too thick.

[0127] Optionally, the connector 3 is welded to the exposed portion 21, or the connector 3 is riveted to the exposed portion 21.

[0128] It is understandable that when the connector 3 is connected to the exposed part 21 of the connecting transition piece 2 by welding or riveting, the connector 3 can form a stable connection with the connecting transition piece 2, preventing the connector 3 from detaching from the connecting transition piece 2.

[0129] Please see Figure 8 In some embodiments, the fourth surface 21b is provided with a connecting portion 26, and the connector 3 is provided with a connecting hole (not shown). The connecting hole is fitted onto the connecting portion 26 so that the connector 3 is positioned or fixed in the exposed portion 21.

[0130] For example, the connecting portion 26 can be milled into the fourth surface 21b, or the connecting portion 26 can be welded onto the fourth surface 21b. Taking the connector 3 as a hinge as an example, the connector 3 can be riveted to the connecting portion 26 of the connecting transition member 2 by opening connecting holes in the leaf, so that the connecting transition member 2 and the connector 3 form a stable connection, and the connecting transition member 2 can also rotate relative to the connector 3. When the connecting transition member 2 is riveted to the leaf of the connector 3 through the connecting portion 26, since both are made of metal, they can be further reinforced by gluing or welding during riveting, which helps to improve the connection stability at the riveting point, thereby improving the stable connection between the magnetic insulation body 11 and the connector 3.

[0131] Optionally, the connection hole can be a through hole or a blind hole, and this application does not make specific limitations.

[0132] Optionally, the surface of the connecting portion 26 at the end away from the fourth surface 21b is lower than or flush with the first surface 1a.

[0133] For example, when the connecting portion 26 is provided, along the thickness direction of the support member 1, the surface of the connecting portion 26 can be lower than or flush with the first surface 1a to avoid the surface of the connecting portion 26 protruding from the first surface 1a, thus preventing the connecting portion 26 from being excessively exposed and affecting the appearance of the support member 1. Moreover, if the connecting member 3 is connected to the connecting portion 26, and the surface of the connecting portion 26 protrudes too high, it will block the contact between the connecting member 3 and the fourth surface 21b, causing a gap between the connecting member 3 and the fourth surface 21b, affecting the stable connection between the connecting member 3 and the connecting transition member 2. In other words, when the surface of the connecting portion 26 is set to be lower than or flush with the first surface 1a, it is easier for the connecting member 3 to form a tight connection with the fourth surface 21b of the exposed portion 21, thereby improving the stability of the connecting member 3 and the connecting transition member 2.

[0134] Optionally, the connecting part 26 includes a plurality of connecting parts 26, which are spaced apart.

[0135] For example, when multiple connecting parts 26 are provided, multiple connecting holes are provided on the connecting member 3 for connection, so that the connecting member 3 and the connecting transition member 2 form a multi-point connection, which is beneficial to improving the stability of the connecting member 3 and the connecting transition member 2.

[0136] It is understandable that the bracket 1 can be attached to the surface of the phone case or phone by rotating the connector 3. If the connecting transition piece 2 is wrapped inside the magnetic insulation body 11, resulting in a thicker magnetic insulation body 11, when the connector 3 is connected to the connecting transition piece 2, the thicker connecting side 1a may prevent the connector 3 from allowing the bracket 1 to be attached to the surface of the phone case, causing the bracket 1 to be relatively tilted, which may affect the appearance and use of the electronic device bracket 100.

[0137] In some embodiments, the thickness of the support member 1 is d1, which can be 1.45mm-1.8mm.

[0138] Please see Figure 9 For example, d1 can be 1.45mm-1.50mm, 1.50mm-1.55mm, 1.55mm-1.60mm, 1.60mm-1.65mm, 1.65mm-1.70mm, 1.70mm-1.75mm, 1.75mm-1.80mm, etc. For example, 1.45mm, 1.47mm, 1.50mm, 1.53mm, 1.55mm, 1.57mm, 1.60mm, 1.63mm, 1.65mm, 1.67mm, 1.70mm, 1.73mm, 1.75mm, 1.77mm, or 1.80mm, etc.

[0139] The overall thickness of the bracket 1 is within 1.45mm-1.8mm. This avoids the bracket 1 from being too thick, which would cause it to warp when connected to the connector 3. It also avoids the bracket 1 from being too thin, which can improve the overall structural strength of the bracket 1 and prevent damage to the bracket 1 during use.

[0140] Optionally, the thickness of the connecting transition piece 2 is d2, which can be 0.5mm-0.7mm. See also... Figure 8 For example, d2 can be 0.50mm-0.55mm, 0.55mm-0.60mm, 0.60mm-0.65mm, or 0.65mm-0.70mm. For instance, d2 can be 0.50mm, 0.53mm, 0.55mm, 0.57mm, 0.60mm, 0.63mm, 0.65mm, 0.67mm, or 0.70mm, etc.

[0141] This application controls the thickness of the connecting transition piece 2 to be between 0.5mm and 0.7mm. When the connecting transition piece 2 is embedded in the bracket piece 1, it avoids the connecting transition piece 2 being too thick, which would cause the bracket piece 1 to be too thick and thus cause the bracket piece 1 to lift up on the surface of the mobile phone or mobile phone case. At the same time, it also avoids the connecting transition piece 2 being too thin, which would result in a poor strength enhancement effect on the magnetically insulated body 11.

[0142] Please see Figure 10 In some embodiments, when the support member 1 is constructed as a ring structure, the magnetic insulating body 11 is also provided with a handle position 1c. When the magnetic insulating body 11 is constructed as a ring structure, the handle position 1c and the connecting transition member 2 are located at opposite ends of the magnetic insulating body 11 along the radial direction of the support member 1.

[0143] It is understandable that the bracket 1 can be attached to the surface of electronic devices such as mobile phones or mobile phone cases via the connector 3.

[0144] Based on this, a handle position 1c can be provided on the bracket 1. The user can lift the bracket 1 by holding the handle position 1c, so that the user can lift the bracket 1 more conveniently and facilitate the user's daily use of the electronic device bracket 100.

[0145] Please see Figure 6 Optionally, the magnetic component includes a first sub-magnetic component 4 and a second sub-magnetic component 5. The first sub-magnetic component 4 is arranged along the circumferential direction of the support component 1 and is located between one end of the handle position 1c and one end of the connecting transition component 2. The second sub-magnetic component 5 is arranged along the circumferential direction of the support component 1 and is located between the other end of the handle position 1c and the other end of the connecting transition component 2.

[0146] In other words, when the first sub-magnetic component 4 and the second sub-magnetic component 5 are disposed within the magnetically insulating body 11, the magnetically insulating body 11 encloses the first sub-magnetic component 4 and the second sub-magnetic component 5 in its thickness direction, so that the first sub-magnetic component 4 and the second sub-magnetic component 5 can form a stable connection with the magnetically insulating body 11. Moreover, the first sub-magnetic component 4 and the second sub-magnetic component 5 are both arranged between the handle position 1c and the connecting transition member 2, that is, magnetic components are provided in the magnetically insulating body 11 on both sides of the handle position 1c and the connecting transition member 2, so that the magnetism can be distributed relatively evenly on the magnetically insulating body 11, which is conducive to the magnetically insulating body 11 stably magnetically adhering to the wireless charger.

[0147] In some embodiments, the two opposing surfaces of the first sub-magnetic element 4 along the thickness direction of the support member 1, and the two opposing surfaces of the second sub-magnetic element 5 along the thickness direction of the support member 1, are both covered by the magnetically insulating body 11, so that the first sub-magnetic element 4 and the second sub-magnetic element 5 are fixed inside the magnetically insulating body 11, and the first sub-magnetic element 4 and the second sub-magnetic element 5 are used for magnetic connection with the charging accessory. When the first sub-magnetic element 4 and the second sub-magnetic element 5 are covered by the magnetically insulating body 11, the two sides of the first sub-magnetic element 4 and the second sub-magnetic element 5 along the radial direction of the magnetically insulating body 11 are covered by the magnetically insulating body 11, and the two surfaces of the first sub-magnetic element 4 and the second sub-magnetic element 5 along the circumferential direction of the support member 1 are covered by the magnetically insulating body 11.

[0148] Understandably, charging accessories can be wireless chargers or portable wireless chargers, for example, magnetic wireless power banks.

[0149] In other words, when the first sub-magnetic component 4 and the second sub-magnetic component 5 are disposed within the magnetically insulating body 11, the magnetically insulating body 11 completely encloses the first sub-magnetic component 4 and the second sub-magnetic component 5 in its thickness direction, circumferential direction, and radial direction, so that the first sub-magnetic component 4 and the second sub-magnetic component 5 can form a stable connection with the magnetically insulating body 11. Moreover, the first sub-magnetic component 4 and the second sub-magnetic component 5 are arranged on both sides of the handle position 1c, so that the magnetism can be distributed relatively evenly on the magnetically insulating body 11, which is conducive to the magnetically insulating body 11 stably magnetically attracting the charging accessory.

[0150] To improve the ease of use of wireless charging, the electronic device holder 100 of this application can be provided with a magnetic component inside the holder 1, so that the holder 1 has magnetism. When the holder 1 is connected to the surface of an electronic device such as a mobile phone through the connector 3, the magnetic component inside the holder 1 can magnetically attract the wireless charger, which also has magnetism. During the charging process, the wireless charger is not easy to fall off due to the magnetic attraction.

[0151] In addition, the first sub-magnetic component 4 and the second sub-magnetic component 5 are evenly arranged on both sides of the bracket component 1, making the magnetism in the bracket component 1 more uniform and making the bracket component 1 more stable when adsorbing the wireless charger.

[0152] Optionally, there may be multiple first sub-magnetic elements 4, which are spaced apart along the circumference of the support element 1.

[0153] Optionally, there may be multiple second sub-magnetic elements 5, which are spaced apart along the circumference of the support element 1.

[0154] For example, when multiple first sub-magnetic elements 4 are enclosed within the support member 1, the space between two adjacent first sub-magnetic elements 4 is filled with the non-metallic material of the support member 1; that is, the first sub-magnetic element 4 is entirely enclosed by the non-metallic material. Furthermore, because there is a gap between two adjacent first sub-magnetic elements 4, the coil inside the electronic device and the coil inside the wireless charger can form an electromagnetic induction through the gap between the two first sub-magnetic elements 4. The gap between the two first sub-magnetic elements 4 can reduce the interference of the magnetism of the first sub-magnetic elements 4 on the electromagnetic induction of the coil inside the electronic device and the coil inside the wireless charger, which is beneficial to improving the charging efficiency of wireless charging. Similarly, the effect of the spacing between the second sub-magnetic elements 5 is the same, and will not be elaborated further here.

[0155] In some embodiments, the first sub-magnetic element 4 is spaced apart from the connecting transition element 2 along the circumferential square of the support element 1. Since the first sub-magnetic element 4 has magnetic attraction, and the connecting transition element 2 is made of metal, when the first sub-magnetic element 4 and the connecting transition element 2 are disposed within the magnetically insulating body 11, and the magnetically insulating body 11 does not moltenly encapsulate the first sub-magnetic element 4 and the connecting transition element 2, their relatively close placement may cause the first sub-magnetic element 4 to attract the connecting transition element 2. Therefore, spacing the first sub-magnetic element 4 and the connecting transition element 2 apart facilitates the arrangement of the connecting transition element 2 within the magnetically insulating body 11.

[0156] Optionally, the second sub-magnetic element 5 is spaced apart from the connecting transition element 2 along the circumferential direction of the support element 1. Since the second sub-magnetic element 5 has magnetic attraction, and the connecting transition element 2 is made of metal, when the second sub-magnetic element 5 and the connecting transition element 2 are disposed within the magnetically insulating body 11, and the magnetically insulating body 11 does not fused and encapsulate the second sub-magnetic element 5 and the connecting transition element 2, their relatively close placement may cause the second sub-magnetic element 5 to attract the connecting transition element 2. Therefore, spacing the second sub-magnetic element 5 and the connecting transition element 2 apart facilitates the arrangement of the connecting transition element 2 within the magnetically insulating body 11.

[0157] Since the first sub-magnetic component 4, the second sub-magnetic component 5, and the connecting transition component 2 can all be made of metal, the first sub-magnetic component 4 and the second sub-magnetic component 5 are respectively spaced apart from the connecting transition component 2 in the circumferential direction of the bracket component 1, so that the bracket component 1 does not have metal material in its circumferential direction, thereby reducing the proportion of metal material in the bracket component 1, thereby reducing the probability of FOD, and thus reducing the impact on the wireless charging effect.

[0158] Please see also Figures 10 to 12 In some embodiments, the thickness of both the first sub-magnetic element 4 and the second sub-magnetic element 5 can be d3, which can be 0.8mm-1.0mm. Exemplarily, d3 can be 0.80mm-0.84mm, 0.84mm-0.88mm, 0.88mm-0.92mm, 0.92mm-0.96mm, 0.96mm-1.00mm, etc. For example, d3 can be 0.80mm, 0.82mm, 0.84mm, 0.86mm, 0.88mm, 0.90mm, 0.92mm, 0.94mm, 0.96mm, 0.98mm, or 1.00mm, etc.

[0159] Since the overall thickness of the support component 1 is approximately 1.45mm-1.8mm, after placing the first sub-magnetic component 4 and the second sub-magnetic component 5 inside the support component 1, the support component 1 needs to be wrapped around the first sub-magnetic component 4 and the second sub-magnetic component 5. If the first sub-magnetic component 4 and the second sub-magnetic component 5 are placed inside the support component 1, the thickness of the support component 1 will be relatively large. This may result in the support component 1 being too thick, which is not conducive to the user's grip. At the same time, due to the overall thickness of the support component 1, the distance between the first sub-magnetic component 4 and the second sub-magnetic component 5 and the magnetic mobile wireless charger will be greater, which may weaken the magnetic attraction effect. Moreover, the excessive thickness of the first sub-magnetic component 4 and the second sub-magnetic component 5 may further affect the thickness of the entire electronic device support 100, which is not conducive to the thin and light design of the electronic device support 100. In addition, placing the first sub-magnetic component 4 and the second sub-magnetic component 5 inside the support component 1 can enhance the overall structural strength of the support component 1 together with the connecting transition component 2. If the first sub-magnetic component 4 and the second sub-magnetic component 5 are too thin, their effect on strengthening the structural strength of the support component 1 will be weak.

[0160] When d3 < 0.8 mm, the overall volume of the first sub-magnetic component 4 and the second sub-magnetic component 5 may be small, which may result in insufficient adsorption force generated by the first sub-magnetic component 4 and the second sub-magnetic component 5. When d3 > 1.0 mm, the thickness of the first sub-magnetic component 4 and the second sub-magnetic component 5 is too large, which is not conducive to the thin and light design of the electronic device bracket 100.

[0161] Therefore, by setting the first sub-magnetic component 4 and the second sub-magnetic component 5 with a certain thickness inside the magnetic insulation body 11, it is possible not only to improve the structural strength of the magnetic insulation body 11, but also to adjust the overall thickness of the magnetic insulation body 11. This satisfies the magnetic attraction effect of the first sub-magnetic component 4 and the second sub-magnetic component 5 on the mobile wireless charger, while also facilitating the overall thin and light design of the electronic device bracket 100.

[0162] In some embodiments, the magnetically insulating body 11 may include a first portion 12 and a second portion 13 along its own thickness direction. The first portion 12 is disposed on one side of the first sub-magnetic element 4 and the second sub-magnetic element 5 along its thickness direction, and the second portion 13 is disposed on the other side of the first sub-magnetic element 4 and the second sub-magnetic element 5 opposite to the first portion 12. The first portion 12 and the second portion 13 are formed integrally to jointly enclose and fix the first sub-magnetic element 4 and the second sub-magnetic element 5.

[0163] It is understandable that when the magnetically insulating body 11 encloses the first sub-magnetic component 4 and the second sub-magnetic component 5, please refer to the following: Figures 9 to 11That is, the magnetically insulating body 11 is a one-piece structure, which integrally encapsulates the first sub-magnetic component 4 and the second sub-magnetic component 5 inside. Hereinafter, to better understand the solution of this application, the integrally formed magnetically insulating body 11 will be structurally described as a first part 12 and a second part 13 along its thickness direction. For example, in... Figure 11 In the middle, the first part 12 is the right side part, and the second part 13 is the left side part.

[0164] For example, when the first sub-magnetic component 4 and the second sub-magnetic component 5 are provided in the magnetically insulating body 11, the first sub-magnetic component 4 and the second sub-magnetic component 5 can be placed on the first part 12 or the second part 13 firstly. Taking the first part 12 as an example, after the first sub-magnetic component 4 and the second sub-magnetic component 5 are placed on the first part 12, the second part 13 can be covered on the first sub-magnetic component 4 and the second sub-magnetic component 5. Then, the first part 12 and the second part 13 are heated so that the first part 12 and the second part 13 can be melted and wrapped around the first sub-magnetic component 4 and the second sub-magnetic component 5, so that the first sub-magnetic component 4 and the second sub-magnetic component 5 are stably wrapped in the magnetically insulating body 11.

[0165] It is understandable that when the connecting transition piece 2 is set inside the magnetically insulated body 11, the connecting transition piece 2 can be set first in the first part 12, and then the second part 13 can be placed on the connecting transition piece 2. Finally, the first part 12 and the second part 13 are heated so that the first part 12 and the second part 13 after being heated and melted can wrap the connecting transition piece 2.

[0166] Please see Figure 11 Optionally, the thickness of the first part 12 is d4, and the thickness of the second part 13 is d5. d4 can be 0.225mm-0.45mm, and d5 can be 0.225mm-0.45mm.

[0167] For example, d4 can be 0.225mm-0.250mm, 0.250mm-0.275mm, 0.275mm-0.300mm, 0.300-0.325mm, 0.325mm-0.350mm, 0.350mm-0.375mm, 0.375mm-0.400mm, 0.400mm-0.425mm, 0.425mm-0.450mm, etc. For example, d4 can be 0.225mm, 0.240mm, 0.250mm, 0.265mm, 0.275mm, 0.290mm, 0.300mm, 0.315mm, 0.325mm, 0.340mm, 0.350mm, 0.365mm, 0.375mm, 0.385mm, 0.400mm, 0.415mm, 0.425mm, 0.440mm, or 0.450mm, etc.

[0168] For example, d5 can be 0.225mm-0.250mm, 0.250mm-0.275mm, 0.275mm-0.300mm, 0.300-0.325mm, 0.325mm-0.350mm, 0.350mm-0.375mm, 0.375mm-0.400mm, 0.400mm-0.425mm, 0.425mm-0.450mm, etc. For example, d5 can be 0.225mm, 0.240mm, 0.250mm, 0.265mm, 0.275mm, 0.290mm, 0.300mm, 0.315mm, 0.325mm, 0.340mm, 0.350mm, 0.365mm, 0.375mm, 0.385mm, 0.400mm, 0.415mm, 0.425mm, 0.440mm, or 0.450mm, etc.

[0169] This application controls the thickness of the first part 12 and the second part 13 to within 0.225mm-0.450mm. This allows for a reduction in the material used in the electronic device bracket 100 while ensuring sufficient mechanical strength of the magnetically insulated body 11. This contributes to the slimmer design of the electronic device bracket 100 and also reduces its manufacturing cost. When d4 and / or d5 are less than 0.225mm, the mechanical strength of the bracket 1 is weak, making it prone to deformation or breakage under external forces, which shortens the service life of the electronic device bracket 100. When d4 and / or d5 are greater than 0.45mm, the overall volume of the bracket 1 is larger, increasing the material used and hindering the slimmer design of the electronic device bracket 100, while also increasing manufacturing costs.

[0170] Optionally, the thickness of the first part 12 and the second part 13 may be equal.

[0171] That is, d4 = d5. In this way, when the support component 1 is subjected to force during use, the force can be more evenly distributed on both sides of the first sub-magnetic component 4 and the second sub-magnetic component 5. In other words, the electronic device support 100 is subjected to balanced force, avoiding stress concentration and reducing the risk of deformation or breakage of the magnetic insulation body 11 due to stress concentration.

[0172] Secondly, please refer to the following: Figure 13 and Figure 14 This application also discloses an electronic device accessory 200, including an accessory body 201 and an electronic device bracket 100 disclosed in the first aspect, wherein the connector 3 is configured to connect the connector transition 2 of the electronic device bracket 100 and the accessory body 201.

[0173] In the electronic device accessory 200 disclosed in this application, a metal connecting transition member 2 is embedded in a non-metallic support member 1, and then a connecting member 3 connects the connecting transition member 2 to the accessory body 201. Since the connecting member 3 and the support member 1 form a stable connection through the connecting transition member 2, when the connecting member 3 is connected to the accessory body 201, the support member 1 and the accessory body 201 form a stable connection, preventing the support member 1 from falling off the accessory body 201.

[0174] Optionally, the accessory body 201 may be a protective shell for an electronic device, or the accessory body 201 may be a ring-shaped support.

[0175] It is understandable that the electronic device protective case can be a mobile phone case, a tablet case, etc. When the main body 201 of the accessory is an electronic device protective case, the connector 3 can be directly connected to the protective case itself, or the protective case can be provided with an annular support, so that the connector 3 can be connected to the protective case through the annular support.

[0176] Taking the annular support as a closed ring as an example. The annular support can be a circular ring, a near-circular ring, or a polygonal ring, such as a rectangle, pentagon, triangle, etc.

[0177] In one example, the main body 201 of the accessory is a protective shell, and the electronic device bracket 100 is rotatably connected to the protective shell. By rotating the bracket 1 of the electronic device bracket 100, the angle between the bracket 1 and the protective shell can be changed, thereby changing the support angle and support height of the electronic device.

[0178] In another example, the accessory body 201 can be an annular support, and the electronic device bracket 100 is rotatably connected to the annular support. By rotating the bracket 1 of the electronic device bracket 100, the angle between the bracket 1 and the annular support can be changed, thereby changing the support angle and support height of the electronic device.

[0179] In another example, the main body 201 of the accessory can be a protective shell with an annular support. The electronic device bracket 100 is rotatably connected to the annular support of the protective shell. By rotating the bracket 1 of the electronic device bracket 100, the angle between the bracket 1 and the annular support can be changed, thereby changing the support angle and support height of the electronic device.

[0180] It is understandable that when the electronic device bracket 100 is placed on the annular support, the electronic device bracket 100 can be accommodated in the groove (not shown) of the annular support to avoid the electronic device bracket 100 protruding relative to the surface of the annular support. When the annular support is placed on the electronic device, it can prevent the electronic device accessory 200 from being too thick, which is beneficial to improving the appearance of the electronic device accessory 200 installed on the electronic device. It can also prevent the electronic device accessory 200 from being too protruding and causing discomfort to the hand.

[0181] Furthermore, when the annular support is installed on the protective shell, the protective shell may also have a groove to accommodate the annular support, so as to prevent the annular support and the electronic device bracket 100 from protruding from the surface of the protective shell. When the protective shell is installed on the electronic device, the surface of the protective shell is relatively flat, which is conducive to improving the appearance of the protective shell installed on the electronic device, and can also avoid the situation where the electronic device accessory 200 is uncomfortable to the touch due to the annular support and the electronic device bracket 100 protruding too much.

[0182] The above provides a detailed description of the electronic device bracket and electronic device accessories disclosed in the embodiments of this application. Specific examples have been used to illustrate the principles and implementation methods of this application. The description of the above embodiments is only for the purpose of helping to understand the electronic device bracket and electronic device accessories of this application and their core ideas. At the same time, for those skilled in the art, there will be changes in the specific implementation methods and application scope based on the ideas of this application. Therefore, the content of this specification should not be construed as a limitation of this application.

Claims

1. An electronic device support, characterized by, The electronic device bracket is configured to support an electronic device. The electronic device bracket includes a bracket, a connecting transition, and a connector. The connector is connected to the bracket via the connecting transition, and the bracket is connected to the electronic device or electronic device accessories via the connector. The bracket includes a magnetically insulating body and a magnetic component disposed on the magnetically insulating body, the magnetic component being used to attract the wireless charger; The connecting transition member includes an embedded part and an exposed part. The embedded part is embedded in the magnetically insulating body, and the exposed part is exposed outside the magnetically insulating body and connected to the connecting member.

2. The electronic device holder of claim 1, wherein, The connecting transition member includes a first end and a second end opposite to each other, the embedded part is located at the first end, the exposed part is located at the second end, and the exposed part extends in a direction away from the magnetically insulating body.

3. The electronic device holder of claim 2, wherein, The exposed portion is provided with a rolled portion, and the electronic device bracket also includes a rotating shaft, which is inserted into the rolled portion and the connector to make the magnetically insulated body rotatably connected to the connector.

4. The electronic device bracket according to claim 1, characterized in that, The connecting transition member is embedded in the magnetic insulating body, which has a first surface and a second surface opposite to each other along its thickness direction. The opposite sides of the embedded portion are covered by the first surface and the second surface, respectively. The first surface is provided with an opening, which is configured to expose the exposed portion to the magnetic insulating body.

5. The electronic device holder of claim 4, wherein, The opening extends away from the magnetically insulating body and penetrates the side of the magnetically insulating body.

6. The electronic device holder of claim 5, wherein, The embedded portion is located around or outside the exposed portion, the exposed portion having a third surface and a fourth surface opposite each other along its thickness direction, the third surface being covered by the second surface, and the fourth surface being exposed to the magnetically insulating body through the opening.

7. The electronic device holder of claim 4, wherein, The connector is welded to the exposed portion, or the connector is riveted to the exposed portion.

8. The electronic device holder of claim 6, wherein, The exposed portion has a convex-shaped structure and includes a main body and a protruding portion. The embedded portion surrounds the main body or the outside of it. The protruding portion extends to the edge of the magnetically insulating body in a direction away from the main body, and the end face of the protruding portion is covered by the magnetically insulating body, or the end face of the protruding portion is exposed to the magnetically insulating body.

9. The electronic device holder of claim 6, wherein, The fourth surface has a protruding connecting portion, and the connector has a connecting hole. The connecting hole is fitted onto the connecting portion so that the connector is positioned or fixed on the exposed portion.

10. The electronic device bracket according to claim 9, characterized in that, The surface of the end of the connecting portion away from the fourth surface is lower than the first surface or flush with the first surface; And / or, the connecting portion includes a plurality of such connecting portions, which are spaced apart.

11. The electronic device holder according to any one of claims 1-10, wherein, The magnetic insulating body is constructed as a ring-shaped structure or a circular structure. The connecting transition member includes a first side and a second side opposite to each other in the circumferential direction of the magnetic insulating body. Both the first side and the second side extend along the circumferential direction of the magnetic insulating body and are both wrapped by the magnetic insulating body.

12. The electronic device holder of claim 11, wherein, Along the thickness direction of the magnetically insulating body, the magnetically insulating body has a first surface. Any point on the projection of the edge of the first side onto the first surface forms a first line with the center of the magnetically insulating body. Any point on the projection of the edge of the second side onto the first surface forms a second line with the center of the magnetically insulating body. An angle α is formed between the first line and the second line, and the range of α is 15°-90°.

13. The electronic device holder according to any one of claims 1-10, wherein, The magnetic insulating body is also provided with a handle position. The magnetic insulating body is constructed as a ring-shaped structure or a circular structure. Along the radial direction of the magnetic insulating body, the handle position and the connecting transition member are located at opposite ends of the magnetic insulating body.

14. The electronic device holder of claim 13, wherein, The magnetic component includes a first sub-magnetic component and a second sub-magnetic component. The first sub-magnetic component is arranged circumferentially along the magnetic insulating body and is located between one end of the handle position and one end of the connecting transition component. The second sub-magnetic component is arranged circumferentially along the magnetically insulating body and is located between the other end of the handle position and the other end of the connecting transition component.

15. The electronic device holder of claim 14, wherein, The two ends of the connecting transition member are respectively spaced apart from the first sub-magnetic member and the second sub-magnetic member, and the magnetic insulating body is filled between the connecting transition member and the first sub-magnetic member and the second sub-magnetic member.

16. An electronic device accessory, characterized in that include: Accessories main body; as well as, The electronic device bracket as described in any one of claims 1-15, wherein the electronic device bracket is connected to the accessory body via the connector.